CH632882A5 - INVERTER WITH SHUTDOWN. - Google Patents

Description

The present invention relates to an inverter with a shutdown circuit and a load.

In order to form reliable power supply sources for critical transmission systems for supplying a critical load, such as that represented by a computer, it is common to use the aforementioned uninterruptible power supply sources which are equipped with inverters which convert a direct voltage into an alternating voltage. The critical load requires a voltage source that is within very narrow tolerance limits in terms of size and frequency. Around

To avoid influences on the load in the event of errors in the inverter, additional power supply sources are switched on on the system, which take over the supply in the event of a failure of one system. However, in order to avoid voltage changes in the transmission system when the inverter fails, the inverters in such circuits are provided with a shutdown circuit. Such inverters can comprise a single-phase or multi-phase inverter, the inverter can have one branch or several branches per phase. Such an io inverter is described in detail in commonly owned U.S. Reissue Patent No. 26,342. Furthermore, the inverter may also be of the type described in the same applicant's U.S. Patent No. 3,207,974.

The object of the present invention is now to create a circuit of the type mentioned above, which is able to shut down the inverter immediately in the event of a fault in the inverter circuit, so as to instantly disconnect the faulty power supply source from the critical transmission system.

This is now achieved according to the invention by the characterizing features of patent claim 1.

An example embodiment of the subject matter of the invention is explained in more detail below with reference to the drawing. Show it:

Fig. 1 shows an inverter circuit with a shutdown circuit and device

FIG. 2 shows a detail of the circuit according to FIG. 1.

1, the circuit shown comprises a self-switching inverter 10, a current direction and threshold detector 12, first and second AND circuits 14 30 and 16, first and second monostable multivibrators 18 and 20 and blocking switches 22, 24, 26, 28 .

The inverter 10 comprises first and second controlled rectifiers 30 and 32 in one branch and in the other branch third and fourth controlled rectifiers 34 and 36, further first to 35 fourth diodes 38, 40, 42 and 44 and first and fourth commutation circuits 46, 48.50 and 52; first and second current limiting chokes 54 and 56; first and second secondary windings 58 and 60 as well as first and second blocking diodes 62 and 64. The rectifiers 30, 32, 34 and 36 furthermore have the diodes 38, 40, 40, 42 and 44 connected in parallel and with reversed polarity. The inductor 54 is connected between the cathode of the rectifier 30 and the anode of the rectifier 32, whereas the inductor 56 is connected between the cathode of the rectifier 34 and the anode of the rectifier 36. The anodes of the rectifiers 45 and 34 are electrically connected to the positive pole of a direct current source, not shown, while the cathodes of the rectifiers 32 and 36 are connected to the negative pole. The commutation circuits 46 and 50 are connected between the positive pole and the center tap of the choke in question 54 and 56; the commutation circles 48 and 52, however, between the center tap and the negative pole. 1 shows that the secondary windings 58 and 60 are inductively coupled to the respective chokes 54 and 56, one end of these secondary windings 58 and 60 being electrically connected to the 55 negative pole and the other ends to the anodes of the associated blocking diodes 62 and 62, respectively 64 are connected. The cathodes of the blocking diodes 62 and 64 are electrically connected to the positive pole. Here, the center tap of the chokes 54 and 56 forms an output for each branch of the inverter 10, between 60 see which outputs are connected in series with a current. transformers 68 and the load 66 is connected.

The control connections Gì, G2, G3 and G4 of the rectifiers 30, 32, 34 and 36 receive their control signals from a control pulse generator (not shown in more detail) in order to switch these rectifiers through in a rhythm determined by the frequency of the desired output voltage at the inverter.

A suitable control pulse generator can also be as described in Chapter 4 of the Silicon Controlied Rectifier Manual, 2.

3rd

632882

Edition, 1961, described by General Electric Company.

Said current transformer 68 in series with the load 66 comprises means which allow the direction and the magnitude of the instantaneous load current to be determined. Here, the output of this current transformer 68 is electrically connected to the input of the detector 12. If the current now flows through the load in a first direction according to the arrow in FIG. 1 and has a size above a threshold value, a first signal appears at the output of the detector 12, which signal reaches the one input of the AND switch 14. If this current flow is greater than the threshold value in the other direction through the load, a second output signal from the detector 12 appears at the other AND switch 16. If an error in the power supply source is then found, such as a switching error in the inverter or a reverse power in the latter , a shutdown signal appears at both UN D switches 14 and 16. If the first detector signal and the shutdown signal reach the input of the AND switch 14 at the same time, an output signal appears at the output of the AND switch 14, which reaches the input of the first monostable multivibrator 18. This then generates a first ignition pulse, which reaches the rectifiers 32 and 34, the connection of which then immediately leads to a bridging of the load and the latter is de-energized. Similarly, if the second signal from the detector and the shutdown signal reach the input of the AND switch 16 at the same time, a corresponding output signal reaches the monostable multivibrator 20. Its output signal then ignites the rectifiers 30 and 36, which in turn instantaneously de-energizes the load.

At this point it should be mentioned that the multivibrators 18 and 20 mentioned can be of any conventional design, provided that they deliver ignition pulses of sufficient duration to switch the rectifiers.

The aforementioned shutdown signal is also fed to the control inputs of the lock switches 22, 24, 26 and 28, which thereupon block any regular firing of the rectifiers in order to achieve a quick shutdown of the inverter.

The current direction and threshold value detector 12 shown in more detail in FIG. 2 here comprises power resistors 70 and 72 and conventional voltage comparison circuits 74 and 76. The resistors are connected between the output of the current transformer and earth and are selected such that their resistance value results in a voltage that can be applied to the input of each comparison circuit. A positive reference voltage + VR is also applied to a second input of one comparison circuit 74 and a negative reference voltage - Vr is applied to the second input of the other comparison circuit 76.

The size of the positive reference voltage + VR and the value of the resistor 70 are selected such that a positive voltage across the resistor 70 arises with a load current in a first direction equal to or greater than the reference voltage + VR, whereupon the aforementioned at the output of the comparison circuit 74 first signal for the AND switch 14 appears. Likewise, the magnitude of the negative reference voltage - Vr and the value of the resistor 72 are selected such that a negative voltage across the resistor 72 arises with a load current in the other direction, equal to or greater than the reference voltage - VR, whereupon the output at the other comparison circuit 76 aforementioned second signal for the AND switch 16 arises.

The predetermined trigger point of the comparator circuits 74 and 76 is so high that the load current does not become zero or change direction upon a shutdown signal until both rectifiers of a branch have switched to the blocking state. This results in a predetermined threshold current according to the equation:

Jt ^

VccAT

where Vcc corresponds to the voltage of the direct current source, ÄT the time for 5 a switching of the rectifiers of a branch into the blocking state and L corresponds to the inductance of the load 66, insofar as this load is inductive.

Thus, for a given threshold current JT, the value of the resistors 70 and 72 and the magnitude of the reference voltage at the comparison circuits 74 and 76 are given.

If, during operation of the circuit arrangement described above, the inverter is to be shut down quickly in response to a fault in the system, the AND switches 14 and 16 are supplied with a stop signal. If the monitored instantaneous current flows through the current transformer 68 and the load 66 in the direction indicated in FIG. 1 and has a value greater than or equal to the predetermined threshold current IT, the voltage across the resistor 70 in FIG. 2 becomes positive 20 and greater or equal to + VR, whereby a first signal is generated at the output of the comparison circuit 74, which signal reaches the input of the AND switch 14. A signal then appears at its output, which reaches the input of the monostable multivibrator 18, which 25 emits a first ignition pulse to the ignition electrodes of the controlled rectifiers 30 and 32. These switch through and trigger a switchover cycle which blocks the rectifiers 30 and 36 within a normal switchover interval of approximately 34 microseconds. This process is described in the aforementioned U.S. Reissue Patent 26,342. As soon as the rectifiers 30 and 36 mentioned are then in the blocking state, the load current flows through the diodes 40 and 42, which switches the controlled rectifiers 32 and 34 into the blocking state. Thus, within a time AT, which is approximately 35 100 microseconds, all controlled rectifiers in both branches of the inverter are brought into the blocking state before the load current changes its direction. Since here the voltage of the power supply source has an inverse polarity with respect to the load current, this source 40 acts as a relatively high impedance, so that when the direction of the load current changes and thus reverse power occurs from the transmission system to the primary winding (load) of the inverter, this high impedance error transmissions to the transmission system until the load current is zero.

45 With the arrangement described above, the load current quickly reaches zero, in a time which is determined by the inductance of the load and the value of external capacitive filters at the output of the system. This time until the current crosses zero is less than 1 millisecond. If the system output is 60 Hz, the period of a half-wave is approximately 8 milliseconds. It can be seen from this that the inverter is shut down within half the time period of the system output signal.

Similarly, if the shutdown signal arrives at 55 the AND switches 14 and 16, if the load current flows in a direction opposite to the direction described and indicated in FIG. 1, the voltage across the resistor 72 becomes negative. If this signal then has a value greater than or equal to the reference voltage - VR, then a second signal will appear at the output of the comparison circuit 76. This again causes a signal at the output of the AND switch 16, which signal reaches the multivibrator 20, which leads a second ignition signal to the controlled rectifiers 30 and 36. These then switch to their conductive state 65 and trigger a switchover process by which the rectifiers 32 and 34 are blocked. Then switch the rectifiers 30 and 32 through, the load current flows through the diodes 38 and 44, whereupon the rectifiers 30 and 36 block.

632 882 4

Now that the shutdown signal is also located at the control inputs of the source. In any case, if only one branch is supplied with the equal blocking switches 22, 24, 26 and 28, the regulating converters 30 and 32 are used and the load current in rich control pulses is independent of the load current direction as shown in FIG. 1 flows, and when further presses the shutdown. Thus, none of the rectifiers of the two branches can signal and the load current exceeds the threshold, switch through again, so that the inverter is stopped. 5, an ignition pulse is generated by the multivibrator 18 and

1, the ignition electrode G2 of the rectifier 32 is supplied, whereupon the load is connected between two inverter branches. It is the inverter branch that is opened. If the load current flows in the opposite direction, but also possible, an inverter with only one branch in the opposite direction, the multivibrator 20 similarly applies, the load then having one end to the co-signal to the ignition electrode Gi of the rectifier 30 tapped the throttle in the branch and with its other 10 ben, thus interrupting the branch.

End is connected to a cell of the DC power source, In the manner described above, it is thus possible through which cell has half the value of the potential of the source. Monitoring the direction and the size of the inverter load - this battery connection can also be connected to the medium current to bring the inverter to a complete shutdown to cause a series circuit to have the same size condenser cycle disturbance or interruption in the inverter, which series circuit in parallel 15 ren.

1 sheet of drawings

Claims (6)

* 632882 2nd PATENT CLAIMS 1. Inverter with a shutdown circuit and a load, characterized in that the inverter a) at least one series circuit, connected via a direct current source, of a first and second controlled rectifier (30, 32, 34, 36) and commutation means (46, 48, 50, 52) for each rectifier, one end of the load (66) being connected at a point between the first and second rectifiers, and that the shutdown circuit b) current sensor means (68) for determining the direction and magnitude of the current load current, c) a detector (12) responsive to the direction and size of the load current for generating a first output signal when the current exceeds the threshold value and flows in one direction. d) circuit means (14, 18) responsive to the simultaneous appearance of a shutdown signal and the first output signal, which generate an output signal for connecting the second rectifier (32, 36) to bridge the load (66), e) has blocking switches (22, 24, 26, 28) responsive to the shutdown signal for blocking the ignition path of the first and second rectifiers to shut down the inverter. 2. Inverter with load according to claim 1, characterized in that the detector (12) has further means for generating a second output signal at a current exceeding the threshold value and opposite to the current flowing in one direction and the switching means (16, 20) simultaneous appearance of a shutdown signal and the second output signal generates an output signal for connecting the first rectifier (30, 34) to bridge the load (66). 3. Inverter with load according to claim 1 or 2, characterized in that a current-limiting choke (54,56) with a center tap is connected in series between the rectifiers (30,32,34,36), at which center tap the load (66 ) connected. 4. Inverter with load according to claim 3, characterized by at least a first and a second branch connected via the direct current source, each branch comprising a series circuit of a first and second controlled rectifier (30, 32, 34, 36), a first and a second diode ( 38, 40, 42, 44) in parallel and with reversed polarity with respect to the rectifiers and the choke (54, 56) between the rectifiers, the commutation means (46, 48, 50, 52) being connected to the center tap of the chokes. 5. Inverter with load according to claim 4, characterized in that the load (66) is an inductive load. 6. Inverter with load according to claim 4, characterized in that the current sensor means (68) consist of a current transformer which is connected in series with the load (66).